Viscous aqueous preparations



3,341,319 Patented Sept. 12, 1967 3,341,319 VISCOUS AQUEOUS PREPARATIONS Billy B. Hibbard, Midland, Mich., assignor to The Dow Chemical Company, Midland, Mich., a corporation of Delaware No Drawing. Filed July 7, 1960, Ser. No. 41,245 15 Claims. (Cl. 71-110) The present invention is concerned with control of the physical properties of aqueous compositions, and is more particularly directed to materials and processes for the preparation of aqueous substances of controlled viscosity.

Of all the liquid media in which substances are dispersed for the more ready achievement or distribution of mechanical, chemical, or biological activity, water is the least expensive and most common. However, when substances are dispersed in water, they usually either dissolve and form a solution of which the viscosity is essentially the same as that of water, or become suspended, temporarily or permanently, in the aqueous medium with the result that the suspension becomes essentially a mass of solid particles possessing their own properties but disposed within water of esentially unincreased viscosity. In many applications, an aqueous medium is of greatly improved utility if its viscosity be simply increased. Such increase, however, must be controllable in the sense that approximately the desired degree of viscosity is established. Moreover, ideally, agents used to increase or control viscosity of fluid preparations should, themselves, be practically inert as to the desired activity of the resulting viscous preparation: that is to say, they should contribute almost nothing but viscosity and should contribute this under virtually all circumstances, and the viscous products should be stable in storage.

' Viscous aqueous preparations have numerous uses. For example, water alone, being rendered of high viscosity by the addition thereto of a minor amount of viscosity increasing substance, becomes a very much more effective agent in such applications as fire-fighting. Also, such viscous inert aqueous preparation is of improved value in the shipment of plant nursery stock whereof it is desired that the roots and other parts of living plants be maintained in a moist condition throughout the period of storage and shipment, until such plants are again established in soil. Whereas water tends to be lost by flowing or dripping away and by evaporation, when the roots and other parts of plants are moistened with a heavy viscous water gel, otherwise inert or at least harmless as to the growth of the plants, they may readily be maintained in moist condition over much longer periods of time and with much less attention than when water alone is used.

In the pharmaceutical and cosmetic fields, it is often desired to apply a pharmaceutical substance or a cosmetic adjuvant as an aqueous preparation; such employment has frequently been hindered because aqueous preparations promptly evaporated to dryness and because it is impractical to build up a deposit of signifiicant depth therefrom. However, by the employment of pharmaceutical and cosmetic substances comprising aqueous preparations together with minor amounts of viscosity-building agents, it is possible to exhibit such substances as pastes, gels, and the like, with correspondingly longer persistence of desired action. In numerous industrial and technological processes, including those wherein the employment of unmoving water is especially indicated by reason of its high specific heat, the employment of thickened or viscosity-increased aqueous preparations frequently permits ready achievement of beneficial results not otherwise available.

Accordingly, it is an object of the present invention to provide means for increasing, to a desired degree, the viscosity of aqueous preparations. It is a further object of the present invention to increase the viscosity of aqueous preparations without significantly alfecting other desired utilities and properties of such aqueous preparations.

It is another object of the present invention to provide a novel and economical aqueous vehicle of which the viscosity may be varied between a viscosity almost as low as that of water and a viscosity greater than can readily be measured, that is to say, a near solid. It is a further object to provide novel aqueous pharmaceutical preparations of pre-determined viscosity up to the viscosity of firm gel-s, embodying pharmaceutical agents normally liquid. It is a further object to provide novel aqueous cosmetic substances and cosmetic adjuvants of desired viscosity up to the viscosity of firm gels, of cosmetic substances and cosmetic adjuvants which are normally liquid. These and other objects will be apparent from the following specification.

According to the present invention I have discovered a viscous, difiiculty flowable essentially aqueous composition of which the components comprise at least a watersoluble polymeric 3-alkenyl cyclic carbamate in the cyclic moiety of which are from 5 to 7, inclusive, atoms and a water-soluble organic polyalkenyl polymer comprising recurring moieties which are members of the group consisting of sulfo and carboxyl and the salts thereof.

The exact chemical structure of the present viscous compositions, and whether a chemical reaction of any sort takes place in their formation, is not known. However, a preparation of the present invention is a composition of which the essential components in aqueous dispersion are a water-soluble polymer comprising recurring 3-alkenyl cyclic carbamate groups in the cyclic moiety of each of which there are from 5 to 7, inclusive, atoms, an da water soluble polyalkenyl polymer comprising recurring members of the group consisting of sulfo and carboxyl and salts thereof; the said composition being of viscosity greater than the mean of the separate viscosities of the said polymers in separate similar dispersion.

Suitable water-soluble 3-alkenyl polymeric cyclic carbamate substances to be employed as one of the two dissimilar components of the novel viscous materials include polymeric N-vinyloxazolidinone, its various water-soluble derivatives such as polymeric 5-methyl-3-vinyl-oxazolidin- Z-one, polymeric 3-vinyl-5-hydroxyethyloxazolidin-2-one, polymeric 3-vinyl-6 methoxyoxazinidin-Z-one, and their position isomers and the like.

Polymeric substances comprising recurring acidic moieties and their derivatives of the sort described which are representative of other of the two dissimilar members of the present vehicle substances include polystyrenesulfonic acid, polyvinylsulfonic acid, polyacrylic acid, sodium polyacrylate, copolymers comprising maleic anhydride hydrolyzed after polymerization, polyvinylbenzoic acid and substituted benzoic acid, partially hydrolyzed polyacrylamide, a hydrolyzed copolymer of vinylacetate and maleic anhydride, a copolymer of styrene and maleic anhydride partially hydrolyzed and thereafter neutralized with sodium hydroxide, a product prepared by the polymerization of styrene and subsequent ring sulfonation to the extent of about 70 mole percent of monomer; and copolymeric substances wherein there recur moities derived from inclusion, in the mixture of monomers, one or more of styrenesulfonic acid, vinylsulfonic acid, acrylic acid, methacrylic acid, vinylbenzoic acid, ring-substituted vinylbenzoic acid, acrylamide, ethacrylic acid, and its higher homoloques, and maleic anhydride in copolymers which are hydrolyzed subsequent to polymerization; and in each case, the salts including the alkali metal salts, ammonium salts, amine salts, and particularly the lower alkylamine and lower alkanolamine salts of the acidic substances of the sort described.

Thus one representative embodiment of the present invention is exhibited in a composition of matter comprising, in aqueous dispersion, the product resulting from the contacting of a water-soluble polymeric 3-vinyloxazolidin-2- one and a water-soluble polyalkenyl substance upon the polymer chain of which there appear recurring moities which are members of the group consisting of sulfo and carboxyl and the salts thereof, said composition being of greater viscosity than the mean of the separate viscosities of the said polymers in separate similar dispersion.

In one manner of carrying out the preparation of the simple viscous aqueous preparation of the present invention, stable homogeneous aqueous dispersions, which may commonly be called solutions, of each of the two said kinds of polymers are first prepared. In this connection it is noted that most such solutions of water-soluble polymers exhibit viscosity moderately higher than the viscosity of water alone. This viscosity, however, is not the thickening or viscosity-building effect of the present invention.

The two separate such aqueous polymer solutions are then combined. The combining is carried out by any convenient means whereby one aqueous solution may be contacted with another. When it is desired to utilize fully the dissolved solids of each of the two said solutions, and to prepare a homogeneous thickened preparation, the combining is carried out in such manner as to provide intimate contact between the two said solutions. This may readily be effected by intimately mixing and stirring the solutions together, preferably with relatively gentle mechanical action. The viscosity that is characteristic of the compositions of the present invention develops promptly after the mixing of the starting materials. Usually, an initial brief interval of low viscosity permits thorough mixing of the starting materials, if such mixing be done promptly. However, if such mixing be carried out violently and past the time when the resulting viscosity has risen to its maximum, the resulting product appears to pass its peak viscosity and decline somewhat in viscosity.

One means of combining starting materials involves the comingling of streams which may be streams issuing from nozzles, whether as solid streams or finely dispersed sprays comprising minute droplets of each separate starting aqueous solution.

When the comingling of such spray-s or other stirring procedure is carried out in gaseous atmospheres such as air, the resulting viscous product tends to entrap inclusions of such gaseous atmosphere. Therefore, when it is desired to prepare such heavy, viscous or near-solid medium without entrapped gas, combining of the starting materials may advantageously be carried out gently: or under atmospheres of reduced pressure or in the absence of gaseous atmosphere. When such gas content is desired, gas may be introduced under pressure to one or both starting material-s or to the resulting product.

In an alternative method of preparation, a thin surficial deposit of one aqueous starting solution may first be deposited from a fixed orifice upon the surface of a rotating drum and a similar thin deposit of a second such starting material may be applied thereto at a point adjacent to the point at which the first such solution was so deposited and, as the drum rotates, it may carry the resulting film of high viscosity past a blade or scraper whereby the resulting viscous vehicle deposit is removed.

In a general method of preparation in which it is possible to prepare all the vehicle compositions of the present invention, one of the two dissimilar aqueous starting solutions is poured, with prompt stirring, into a container containing the other of the two dissimilar starting solutions, such container having a capacity adequate to hold the combined result, stirring being continued only long enough to effect complete dispersion of each such aqueous preparation in the other. This method is Well adapted to be employed in the preparation of all the vehicles of the present invention of low to moderate viscosity and, without undue difficulty may be used in the preparation of even the most viscous vehicles of the present invention.

The starting material solutions of the sort described may also each be brought separately through hose, tube, pipe, or conduit to a junction or confluence at and beyond which mixing takes place or is caused, by induced turbulence, to take place, and the resulting viscous product is then further disposed in any desired manner.

The aqueous starting solutions may comprise pharmaceutical or cosmetic substances, chemically, biologically, or physically active substances, or stable aqueous dispersions of such substances in water-compatible form such as solutions in water-miscible solvent or dispersion in stable aqueous emulsion.

When one or both of the said aqueous polymer solutions comprises such active substance, the said substance becomes embodied in the resulting thickened or viscous preparation.

There may also be prepared a composition of matter comprising the product resulting from the intimate mixing together in aqueous dispersion of an adduct of a polymeric vinyloxazolidin-Z-one compound and a biologically active material with a polyalkenyl substance comprising recurring moieties selected from sulfo and carboxyl and salts thereof.

Although the uncombined starting solutions to be employed in the present method of preparing a viscous product of the present invention may be heated at any temperature over the liquid range of water, that is, between 0 C. and C. without injury, the resulting viscous preparations tend to be somewhat heat sensitive. This heat sensitivity does not appear to exhibit sharply defined limits. Between about 0 C. and approximately 20 C., temperature changes have little or no effect upon the present viscous product. Between about 20 C. and about 50 C. increasing temperatures are accompanied by gradual decrease in viscosity, and the full original viscosity as measured at about 20 C. is largely recovered as the prod-uct is cooled. As the temperature of a viscous product of the present invention is increased gradually from about 50 C. to about 70 C., the viscosity further declines, but again most of it is recovered upon cooling. Similarly, as heating is continued to approximately the boiling temperature of water, viscosity 'of the present products further declines rapidly, but almost all of the viscosity is recovered upon cooling. However, at temperatures only slightly lower than the boiling temperature of water, the present products yet retain a viscosity substantially higher than the average of the viscosities of the starting material at the same temperatures. Exact numerical values for the such declining viscosities can be derived only in the instance of particular compositions and treatments, and vary according to factors not yet completely known. No quantitative means of predicting such thermal viscosity change in advance is now known. Preparation of the present products is best carried out with both aqueous solutions at any temperature at the lower end of the temperature range at which the starting polymeric substances are conveniently dissolved in the desired starting concentration. Such temperatures usually are room temperature, about 24 C.; or the temperature of industrial process feed-water, usually from about 7 to about 22 C. However, when it is desired to employ distilled or heat-sterilized water in the preparation of the starting aqueous solutions, aqueous still-condensate may be employed at any temperature at which it is conveniently collected, assuming the starting polymeric substance to be soluble in water at such temperature. The resulting hot solutions need not be cooled before continuing to prepare the present products.

The exact concentration of aqueous solution of starting polymeric substances depends upon various factors and may vary over a considerable range. When it is desired to prepare a vehicle of which the viscosity or thickness will develop precisely within narrow limits, it may be necessary, in any individual preparation, to carry out simple range-finding tests. Thus, the desired viscosity of the resulting product is a major factor in the determination of the concentration in aqueous solutions of the starting polymeric substances.

In a second general manner of practicing the present invention, a viscous product is prepared by dispersing in aqueous medium the essentially dry product resulting from the intimate mixing and blending together in finelydivided form of a water soluble polymeric 3-alkenyl cyclic carbamate having from to 7, inclusive, members in the ring, and a water-soluble polyalkenyl substance comprising recurring moieties which are members of the group consisting of sulfo and carboxyl and the salts thereof.

Numerous methods for effecting such mixing and blending are well known to those skilled in the art, one representative method being the use of a ball-mill.

In a typical manner of carrying out such preparation, the said polymeric substances are combined in the desired proportion, usually in the absence of liquid medium, and are then intimately mixed and blended together to effect uniformity of the resulting mixture.

Such uniform resulting mixture is then dispersed or dissolved in water to obtain a homogeneous uniform aqueous dispersion which promptly assumes the viscosity of the product of the present invention.

No theoretical explanation is known, for the viscosity increase of the present invention. Therefore, it is not at present possible to state precisely what proportions of the two solid components of the resulting viscous material represents the optimum of efiiciency and economy.

Good results are obtained when employing amounts of the solid materials in which the number of recurring cyclic carbamate moieties is equal with the number of recurring acid moieties; apparently equally good results are also obtained when employing equal actual weights of the two different kinds of substances, at least when each is a homopolymer. However, good results are obtained when employing the starting polymeric materials in very dissimilar amounts.

For example, when employing starting polymer solutions each in a concentration of /2 percent solid by weight of resulting solution, good thickening and a very substantial increase over the viscosity of the starting materials is obtained when employing a mixture comprising 1 part of sodium polystyrene sulfonate solution and 9 parts of polymeric 5-methyl-3-vinyl-oxazolidin-2-one solution. Similarly, a mixture comprising 9 parts of sodium polystyrene sulfonate solution and 1 part of polymeric S-methyl-3-vinyl-oxazolidin-2-one gives a distinctly thickened resulting product.

When employing the said /2 weight percent solutions of the said starting materials, maximum thickening appears to be achieved when employing approximately 25 part of polymeric 5-methyl-3-vinyl-oxazolidin-2-one and approximately 75 parts of sodium polystyrene sulfonate solution. Such proportion is not, however, critical or essential for the practice of the present invention.

The viscosity of the resulting products of the present invention appears to be related in some way which is not fully understood to the concentration of the starting materials in aqueous dispersion. No particular amount or concentration or related ratio of amounts of concentrations of the polymeric substances in aqueous dispersion is known or believed to be essential or critical, but good results are obtained when employing starting solutions containing ten weight percent of each substance. The resulting products commonly achieve a viscosity so great as to be solids. When it is desired to prepare substances of considerably less viscosity, concentrations of one weight percent of each of the starting polymeric substances in water are usefully employed. The resulting products appear to be soft solids or near-solids.

When it is desired to prepare an aqueous composition of which the essential components are a mobile aqueous solution of a polymeric N-vinyl cyclic carb'amate in the cyclic moiety of which there are from 5 to 7, inclusive atoms and a polyalkenyl polymer upon which there are recurring moieties which are members of the group consisting of sulfo and carboxyl and salts thereof, having a viscosity greater than the mean of the separate viscosities of similar separate solutions of the said polymers, but yet a relatively low viscosity, concentration of solids as low as 5 one-hundredths of 1 percent of the resulting aqueous starting material solution may be employed.

Measurable and distinctive increases in viscosity over the sum of the viscosities of the starting substances are obtained when employing concentrations of the polymeric starting materials in water as low as one one-hundredth percent by weight of resulting solution. It is believed after examination of many aqueous preparations, that if techniques for the precise measurement of viscosity were more refined than are presently available, concentrations as low as one one-thousandth weight percent would be found to give measurable and distinctive increases in at least some of the properties collectively called the viscosity of the mixtures resulting from the combination thereof. Such concentrations of the product of the present invention are found to modify the properties of aqueous media perceptibly.

Other factors have been found to have effect upon the viscosity of the resulting preparation. One such factor is the degree of polymerization, that is to say, the molecular weight, of the starting polymeric substances. Polymeric starting substances of relatively high molecular weight appear to be especially useful. Thus, when employing, as polymeric substance of the acidic type, the salt of polystyrene sulfonic acid prepared by neutralization of the sulfonic acid moieties, or most of them, good results and great thickening are obtained when employing a sodium polystyrene ulfonate having an average molecular weight of about one million or higher. Such starting polymer, in aqueous solution in a concentration of about 2 percent :by weight of the resulting solution, readily takes part in the preparation of firm gels, although such aqueous starting solution is relatively thin and watery. Similarly, sodium polystyrene sulfonate solutions of similar concentration prepared from a starting polymer salt of which the average molecular weight is about 800,000 also give rise to very firm vehicles. By the employment of lower concentrations or polymer of lower molecular weight, or both, it is possible to prepare vehicles having lower viscosity.

Average molecular weights of the heterocycle substituted polymeric substance are desirably of at least the same general order, and, advantageously, higher. In terms of the K-value of Fikentscher, good results are obtained when employing polymers having K-values of from 20 to 70. Higher K-values are advantageous. However, no upper or lower limit molecular weight has been found to be critical.

It has elsewhere been discovered that at least some polymer compounds useful as the heterocyclic member of the present viscous mixtures will form stable adducts with many substances. Such adducts are believed to be the subjects of patent applications to which the present inventor is not privy.

However, such adducts, as supplied to the present inventor by others, have been employed and have been found to take part in forming the present vehicle materials of increased viscosity without disturbing the state of the adduct, or liberating any component thereof. It is thus determined that the state of the said heterocyclic polymer substance, whether combined in some kind of complex structure, or uncombined, is immaterial in the practice of the present invention.

In one embodiment of the present invention, the

viscosity-building action and preparation of a vehicle according to the present invention may be carried out in situ by separately applying, to the desired site, the necessary starting substances. The following examples serve to illustrate certain methods of preparation, products and the processes embodying and utilities employing the present invention, but are not to be considered as limiting.

Example 1 A sodium styrene-p-sulfonate monomer was polymerized in known manner to obtain a relatively pure sodium polystyrene-p-sulfonate having a mean molecular weight of approximately 800,000 as determined by a standard light-scattering method. This polymer was dissolved in water to prepare a colorless neutral slightly viscous solution containing 2.5 percent of polymeric material by weight of total solution. For convenience, this solution will in the present example be referred to as the sulfonate solution.

A 3-vinyl-S-methyloxazolidin-Z-one polymer of which the molecular weight may be characterized by the K- value of 59.9 according to the method of Fikentscher (see Cellulosechemie 13, 60 (1932)), as a fine powder, was dissolved in water to prepare a solution containing 2.5 percent of the said polymeric 3-vinyloxazolidin-2-one compound. This solution will hereinafter, for convenience, be referred to as the oxazolidinone solution.

Equal volumes of the sulfonate solution and the oxazolidinone solution were contacted together quickly, with stirring at room temperature to prepare a thickened vehicle of the present invention. The mixture promptly assumed a viscosity very much higher than the viscosity of either starting solution, becoming a soft semi-solid.

The viscous mixture was disposed in the open filler (bottom) end of an empty flexible dispensing tube which was then closed and sealed. The head of the tube, comprising a threaded neck to which a screw cap Was affixed was exposed by unscrewing and removing the said cap and puncturing the head membrane. Through the puncture thus provided, the viscous product was readily expressed and applied as a viscou solid to surfaces upon which it was desired to effect such application. Upon being spread by application of pressure of an index finger the viscous vehicle formed an intact film or fluid membrane which appeared to be uniformly continuous. Such film exhibited no tendency to flow, drip, or run under direct application of pressure intended to displace it; the film was strongly adhesive.

Example 2 In the present example an aqueou solution of sodium polystyrene sulfonate Was prepared identical with that employed in Example 1. As the cyclic carbamate substituted polymeric aqueous solution there was employed an adduct of a biologically active material prepared as follows: a 3-vinyl-5-methyl-oxazolidin-2-one polymer having a molecular weight characterized by its K-value according to Fikentscher of 59.9 was dissolved in a solution of 4 grams of iodine in a mixture of 20 milliliters methylene chloride and 500 milliliters of carbon tetrachloride; The resulting dispersion was agitated at room temperature for 18 hours and thereafter the solid component was removed by filtration and washed repeatedly With carbon tetrachloride and with diethylether and then maintained at a temperature of 40 C. under subatmospheric pressure for approximately 18 hours to remove traces of solvent and achieve equilibrium dispersion of the halogen. The resulting solid adduct substance contained a substantial proportion of bound iodine. It was dissolved in water to prepare a solution containing 2.5 percent of the halogenpolymer adduct substance by weight of resulting aqueous solution. For convenience, this solution will, in the present example, be identified as the iodine-polymer solution. Equal volumes of the sulfonate solution and the iodinepolymer solution were intimately mixed and blended together with stirring at room temperature. The mixture promptly became homogeneous and of a viscosity very much higher than the viscosity of either starting solution, achieving a viscosity apparently as great as that described for the product of Example 1.

The viscous mixture was placed in the open end of an empty flexible dispensing tube as was the product of Example 1. The tube was then closed and sealed and in procedures such as were outlined in Example 1, the resulting viscous iodine-bearing solution was applied to localized areas of human skin. Upon being spread by the application of pressure of a forefinger, the viscous iodinevehicle material formed an intact film or fluid membrane of uniform and continuous nature having no observable tendency to flow, drip or run. It was not completely removed by the direct application of finger pressure intended to try to remove it. The product prepared in this example contained 0.125 percent of iodine in total formulation corresponding to 5 percent iodine by weight of total solids. The product was found to be strongly germicidal.

Example 3 The present example was carried out in all respects as was Example 2 except that the employed aqueous solutions of the starting polymeric substances contained 1 percent by weight of resulting solution of each of the polymeric materials. Each of the said polymeric starting solutions had a viscosity only slightly higher than that of water. However, the vehicle resulting when the said solutions were combined was of the viscosity of a thick salve. When introduced into and dispensed from a plastic dispensing tube in the manner hereinbefore described, this product, applied to and spread over a surface area with the resulting formation of a film has no observable tendency to run, drip or How.

Example 4 The present example is carried out in all respects as was Example 1 except that, instead of a sodium polystyrene sulfonate solution there is employed an ammonium polystyrene sulfonate solution containing approximately 14 percent ammonia in uncombined form in the resulting aqueous solution. This may be understood to be a 2.5 weight percent solution of ammonium polystyrene sulf-onate in aqueous ammonia. A portion of such starting solution is set aside for comparison purposes. A further portion is combined with an equal volume of oxazolidinone solution as hereinbefore described. Upon the combining of the polymeric sulfonate and oxazolidinone solutions, thickening promptly takes place with the result that there is prepared an extremely viscous semi-solid essentially fluid preparation of ammonia. A portion of such solid is set aside for comparison with the afore-mentioned sample of the ammonium polystyrene sulfonate solution in aqueous ammonia. The preparations are covered and maintaned at room temperature and with periodic tests for escape of ammonia and for remaining ammonia content. At the end of 72 hours, the simple ammonium polystyrene sulfonate solution in aqueous ammonia is found to have lost most of its ammonia content. In contrast, the thickened ammonia gel of the present invention is found, at the end of 72 hours, to have a content of ammonia not much less than the starting concentration. The gelled ammonia product of the present example is useful in application wherein aqueous ammonia is called for, with the improvement that the present composition may be handled as a solid.

In a similar pre aration a gel comprising aqueous 14 percent ammonia and, as viscosity increasing agents, sodium polystyrene sulfonate and polymeric -methyl 3- I vinyl-oxazolidin-Z-one was prepared, covered, and set aside. At the end tained, practically ammonia content.

A similar preparation was prepared comprising aqueous ammonia in 5 percent concentration; and was found to be similarly stable.

of two years it was found to have reunaffected, its original viscosity and Example 5 In manner essentially similar to the foregoing example there is prepared a gel comprising aqueous sodium polystyrene sulfonate and aqueous polymeric 5-methyl-3-vinyloxazolid-in-Z-one together with one percent by weight of resulting product of sodium hydroxide. The resulting viscous material has a pH substantially above 9, and is adapted to be employed as a cosmetic adjuvant for topical application to human fingernails for the softening of cuticle preparatory to its cosmetic rem-oval.

Example 5 A hose comprising two parallel laterally joined flexible tubes is provided with a nozzle whereby the contents of the tubes are intimately contacted together at the last instant of their traverse of the tubing and prior to issuing from the said nozzle. Through one tube is supplied a one weight percent aqueous solution of sodium polystyrene sulfonate and through the other tube is supplied an aqueous solution of a water-soluble polymeric alkenylsubstituted cyclic carbamate, in the present example an aqueous one weight percent 3-vinyl-5-hydroxyethyloxazolidin-Z-one. Each of the two liquid supplies, of very low viscosity, contains, as opacifier, a small amount of titanium dioxide. The solutions flow freely through their respective tubes; upon mixing in the said nozzle, the result ing composite solution promptly assumes the greatly increased viscosity characteristic of the products of the present invention, being in effect, water of greatly increased viscosity and adhesivity. The liquid issuing from the said nozzle is directed at a fire which is destroying a wooden structure. The resulting viscous, opacified water material readily adheres to the wooden structure and tends to build up a cooling, reflective deposit of substantial depth. As a result of these operations, the fire is not only superficially extinguished, but confined, superheated areas of combustible substances are cooled by the resulting deposit of jelled water substance, assisted by the presence of the opacifier, thus obviating the need, often noted in professional extinction of damaging fires, to continue to cause a flowing stream of water to contact the remaining portions of the wooden structure. Thus the present product is of special value in fire fighting with restricted water supplies, or where flooding from excessive use of water is to be avoided.

In another embodiment of the instant aspect of the present invention, the said nozzle is elongated and provided with means for the introduction into the polymer solution stream, subsequent to the mixing of the said solutions, of compressed gas. In the instant example the gas is co-mpresed carbon dioxide. The judicious selection of rate of gas introduction with respect to viscosity of the resulting product makes possible the production of a foam comprising the present jelled water substance with abundant included bubbles of inert gas.

10 Example 7 There is provided a herbicidal solution containing, as a principal active ingredient, the alkanolamine salts of the ethanol and isopropanol series of 2,4-d'initro-o-secondary butylphenol. To the aqueous solution of the said herbicidal substance there is added one percent by weight of resulting solution of polymeric 5-methyl-3vinyloxazolidin-2-one, the said polymer having a molecular aggregation as represented by the K-number according to Fikents- 'cher of 60.

There is provided a second solution comprising one and one half percent by weight of resulting solution of sodium polystyrene sulfonate. Each of the said solutions is placed in a separate tank in a sprayer designed to apply compressed air pressure to the contents of both tanks simultaneously, means for the control of the issue of each such liquid from its container, and a nozzle wherein the two solutions are mixed together at the last instant before leaving the said apparatus.

Compressed air pressure is applied, the nozzle is directed toward vegetation which it is desired to kill, and the control means are operated to permit the two solutions to issue from their containers, mixing at the last instant while yet remaining in the equipment, to prepare a heavy, yellow clinging, viscous aqueous dispersion of the said herbicide in a jelled preparation according to the present invention. The resulting viscous substance clings to the above-ground parts of the plants upon which the preparation is caused to be deposited. As a result of these operations, there is applied a deposit of herbicidal toxicant having eifect upon the plant of longer persistence and, on an average of a large number of plants, more complete kill. In a related process, separate solutions of 0.1 weight percent of the two gelling substances were employed, and the herbicide was an ester of 2,4-dichlorophenoxyacetic acid. The viscosity increase was achieved prior to application. The resulting syrupy liquid preparation had a viscosity of 1000 centipoises, Brookfield.

The viscous preparation was readily applied to a test area from a compressed air sprayer. The applied substance was virtually free from air-borne random particles and thus did not cause drift injury to adjacent areas.

Example 8 In a soil conservation district comprising approximately 600,000 acres disposed over the head-waters of a small stream there are, as principal watershed of such stream, 12 farms upon the land of each of which there is a catchment. The said catchments are used by the operators of the said farms as ponds for watering live stock, for recreational swimming and fishing, and for other uses. In seasons of acute rainfall, the catchments customarily fill to overflow and thus contribute, to the small stream about whose head waters they are disposed, water in volume greater than lower reaches of the bed the stream can readily accommodate; with the result that portions of the stream and its environs are subject to sudden, brief, damaging floods.

Into each of six of the said catchments there is introduced sodium polystyrene sulfonate. Into each of the remaining six there is introduced 5-methyl-3-vinyl-oxazolidin-2-one. The said substances are introduced into the catchments at rates corresponding to approximately one tenth of one percent by weight of water. No individual catchment is seriously affected by the introduction of one of the relatively inert substances in small amounts. However, upon the occurrence of a short, sharp rainfall as the catchments overflow and their waters comingle in the said small stream, the resulting mixed solution of the two substances becomes of greatly increased viscosity with the result that, while it flows through the stream bed, such flow is of greatly reduced rate, and flooding does not occur. As the rainfall continues, and further flow of water takes place, the water of increased viscosity is greatly diluted and carried downstream so that, a few miles below the site where the flooding was prevented no further evidence of the preventive means appears.

Example 9 A polymeric -methyl-3-vinyloxazolidin-2-one having a K-value according to Fikentscher of 30 was dissolved in water to obtain a colorless solution thereof containing 5 percent by weight of resulting solution of the said polymer. This solution was found to have a Brookfield viscosity, as measured at 60 r.p.m., of from 4 to 5.5.

A second solution was prepared, comprising a copolymer of vinyl acetate and maleic acid. Such solution, containing 5 percent of the said polymer by weight of resulting solution was found to have a Brookfield viscosity, when measured at 60 rpm. of 235 centipoises. The same solution was then diluted with further water to obtain a concentration of 2.5 percent of the said polymer by weight of total solution. At such concentration, the Brookfield viscosity measured at 60 r.p.m. was 39 centipoises. The additive sum of the viscosities of such solutions of 2.5 weight percent concentration of each of the two said polymers would be between 40 and 45 centipoises.

Equal portions of 5 weight percent solutions of the copolymer of vinyl acetate and maleic anhydride and the polymeric 5-methyl-3-vinyloxazolidin-2-one in water were mixed together. The resulting mixed solution, comprising 2.5 weight percent of total resulting solution of each of said components was immediately intimately mixed and stirred. Thereupon, the viscosity of the resulting mixture promptly increased. The resulting viscosity was measured and found to be 228 centipoises, approximately five times the sum of the viscosities of the separate compounds.

Example A 1 percent aqueous solution of polymeric 5-methyl-3- vinyloxazolidin-Z-one is intimately mixed and blended with a 1 percent aqueous solution of a commercial flocculant which is a polyacrylamide partially hydrolyzed after polymerization to obtain a substantial fraction of acidic moieties on the polymer chain. The two said solutions are combined with mixing and stirring and promptly thereupon the resulting mixture undergoes a great increase in viscosity.

Example 11 Two aqueous 1 percent by weight solutions are prepared, one containing polymeric 5-methyl-3-vinyloxazolidin-Z-one having a K-value according to Fikentscher of 80. The other contains a copolymer of styrene and maleic anhydride hydrolyzed subsequent to polymerization to obtain a polymer upon which there are recurring carbo-xyl radicals attached to the hydrocarbon chain. The resulting hydrolyzed polymer is thereafter neutralized with sodium hydroxide to obtain a sodium salt of the carboxyl groups. Each of the separate solutions is colorless, bland, and of a viscosity not apparently much greater than that of water.

The two solutions are combined with immediate mixing and stirring, and promptly thereupon the resulting mixture increases in viscosity to become a firm gel.

Example 12 Two aqueous 1 weight percent solutions are prepared One of the said solutions contains polymeric S-methyl- 3-vinyl oxazolidin-Z-one having a K-value according to Fikentscher of approximately 70'. The other contains a commercial polymeric material, essentially a polymer of styrene sulfonated subsequent to polymerization to introduce thereinto, primarily upon the aromatic nuclei thereof, sulfonate groups corresponding in number to approximately 70 percent of the aromatic nuclei. The resulting substance is strongly acidic and is of limited solubility in water. Each of the said solutions is colorless, and of a viscosity apparently only slightly greater than that of Water.

The two solutions are mixed and quickly stirred together, whereupon there promptly forms a very viscous gel.

Example 13 from the said vehicle substance. The resulting dry material was scraped from the surface whereupon it was dried, and, by simple crushing reduced to an amorphous irregular powdered material. This powdered material was then placed in a capped glass container and held in storage for a period of several months.

At the end of this time, the substance was removed from its container, dispersed in water, of amount approximately equal to the amount originally employed in preparation of the product. As a result of these operations there was obtained a reconstituted viscous material, the viscosity of which was nearly as great as the original viscosity of the vehicle prepared prior to drying.

The resulting reconstituted viscous material was thereafter again dried and again reduced to a white solid which was subsequently powdered and again placed in storage. After several weeks in such storage the powdered material Was again reconstituted with essentially the same amount of water and upon examination was found to possess viscosity much greater than the original viscosity of the separate starting polymeric solutions from which the original product had been prepared, but somewhat lower than the gel initially prepared by mixing the said original water solutions.

Example 14 A viscous material similar to the product of Example 1 was prepared, differing in that the starting polymeric vinyloxazolidin-2-one had a greater molecular weight corresponding to the K-value according to Fikentscher of approximately 80. The resulting gel was sufiiciently firm that it did not flow from a container confining it, when the container was inverted.

The resulting gel was placed in the container of a high speed impeller-type mixing device (Waring Blendor) and subjected to high-speed shear mixing. The speed of the impeller was greatly reduced as compared with its speed when operating in water. Continued operation of the impeller resulted in a gradual decline in the viscosity of the viscous preparation. After 5 minutes of operation, the temperature of the viscous preparation thus agitated was noted, and was found to have risen, as a result of the mixing and blending action, from an initial temperature of approximately 22 C. to a temperature of approximately C. This was interpreted as a manifestation of the inner resistance of the viscous material to the shearing action of the mixing device. The viscosity of the material increased as the temperature of the product declined to room temperature.

Example 15 Equal weights of polymeric 5-methyl-3- vinyloxazolidin-Z-one and sodium polystyrene sulfonate of the sort employed in Example 1 were mixed and blended together dry. The resulting dry mixture was thereafter taken up in water to obtain an approximately 1 weight percent solution of each of the said starting materials. Immediately upon the combining of the dry mixture with water, there resulted an increase in viscosity, and the preparation of a material much more viscous than would have been an aqueous solution of either star-ting material alone.

The viscous preparation is placed in storage and held therein for 18 hours. At the end of this time, the preparato be of viscosity substantialsame preparation at the end ase.

Example 16 Polymeric 5-methyl-3-vinyloxazolidin-2-one having a molecular weight corresponding to the scher of 60 is dissolved in containing 2.5 percent by K-value of Fikentprepare a solution the said polymer.

water to weight of Into the resulting solution there is dispersed an amount of sodium phenate equimole' oxazolidinone units of the phenate disappears apparently with the odor of phenol d cular with the recurring vinylsaid polymer. The sodium by dissolving, and thereisappears also. The resulting solution, comprising an adduct of some kind, of the sodium phenate with the said polymer, is germicidal and innocuous upon contact with tissues of warm-blooded animals. It is strongly germicidal. However, its germicidal use is handicapped by its relatively low viscosity.

It is desired to prepare 21 comprising such adduct.

much more viscous product To the said adduct solution there is added a second solution comprising an amount of sodium polystyrene sulfonate of weight equal to the oxazolidinone polymeric material.

weight of the starting Immediately upon the combination of the two said solutions, they are intimately mixed and blended by prompt, vigorous stirring. The resulting mixed solution immediately increases very greatly in viscosity to obtain a highly viscous gel.

An infrared 5-methyl-3 -vinyloxazolidin-2 spectrum scan of the adduct of polymeric -one and sodium phenate indicates a significant displacement and other modifications of the spectral bands deriving from the carbonyl group of the oxazolidinone material cal. This disturbance of the said adduct and from the phenate radispectrum indicates that the represents a significant chemical modification of each starting material. The gel product of the present example is similarly examined by infrared-scan and also exhibits the said displacements, indicating that the formation of the present gel does not disturb nor apparently involve the mechanism of the formation of such adducts. The gelled product of the present example is tested in standard microbiological techniques and found to be strongly germicidal.

Example 17 A definitive test was, set thickening which is characte up to ascertain whether the ristic of the present invention does or does not disturb adducts of water solutions of alkenyl substituted ized substances. It material,

of aqueous solutions of such alkenyl cyclic carbamate polymers is the sodium salt of polymeric styrene-p-sulfonate. It is reasoned that if the thickening according t by reason of formation of lar to that wherewith other the present invention arises an adduct in a mechanism simiadducts of the sort described are formed, then an aromatic sulfonate adduct of the said alkenyl cyclic carbamate polymer, having no further capacity to combine'with such sulfonate groups, should be incapable of forming sulfonate, according to Such adduct was prepared ous solution, of polymeric one and benzene sulfonic further adduct with a polystyrene the present invention.

by the combination, in aque- 5-rnethyl-3-vinyloxazolidin-Z- acid in amounts equimolecular upon the basis of the recurring vinyloxazo'lidinone units in the polymer, and the benzene sulfonic acid molecule.

Both substances are readily and promptly soluble. Examination of the spectrum derived by infrared scan of the starting materials and the displacement corresponding resulting adduct indicates a to a major modification of To the aqueous solution of such adduct there was added an equal weight of polystryrene sulfonic acid also in aqueous solution. The two solutions were immediately intimately mixed and stirred, and propmptly thereafter the resulting mixed solution increased greatly in viscosity, and formed a firm gel. The examination of the resulting gel, in various systems of analysis, fails to disclose the presence therein of uncombined nonpolymeric benzene sulfonic acid. The sulfonic acid moieties of the polystyrene sulfonic acid appear to be present in essentially unmodified form.

Example 18 Polymeric 5-methyl-3-vinyloxazolidin-2-one having a macromolecular weight corresponding to a K-value of Fikenstcher of 63.5 was dissolved in natural sea water representative of the waters of the high seas to prepare a solution containing 1 percent of the said polymeric substance by weight of resulting seawater solution. Similarly, a solution was prepared comprising 1 percent of sodium polystyrene sulfonate by weight of resulting seawater solution. The two solutions, at room temperature (approximately 24 C.) were then poured together and intimately mixed by manual stirring. The resulting mixture promptly increased in viscosity, the viscosity increasing as stirring continued for a per'od of a few minutes. The resulting highly viscous product was set aside for a. period of time and observed.

After standing for about an hour, the viscous preparation exhibited what appeared to be some kind of internal structure. The appearance of such structure seemed to derive from possible differences in refractive index of different portions of the viscous body, although previously all parts had apparently been entirely homogeneous. The visible structure, which was colorless, appeared to take the form of lines, planes, or segmentations of some kind. Thereafter, the viscous preparation apparently underwent some kind of syneresis, increasing in viscosity, decreasing in size, and weeping a watery exudate. The preparation was further set aside and further observed for approximately '60 hours. At the end of this time, the viscous mass has increased greatly in viscosity, shrunk in size to about one tenth its original volume, and had released water corresponding in volume to the volume loss of the viscous mass.

Example 19 The present example is similar to the foregoing in that the aqueous medium employed is sea water, and the polymeric starting materials are the same, but the preparation is carried out in a different manner.

Equal weights of sodium polystyrene sulfonate having a molecular weight of approximately 150,000 and polymeric 5-methyl-3-vinyloXazolidin-2-one having a macromolecular weight corresponding to a K-value of Fikentscher of about 63.5 are intimately mixed and blended together and thereafter, in the dry form, placed together in a ball mill where they are commingled for a period of about 5 hours to reduce the resulting product to a fine powder and provide intimate mixing of the starting,

polymeric substances.

The resulting impalpable powder is strewed gently on the upper surface of a body of sea water. Coarser particles of the powdered material promptly break through the surface tension of the water and thereafter settle through the water towards the bottom. All the particles, including those settling, appear to disperse in the water to prepare a heavy viscous jelly-like substance in the form of an aqueous dispersion of the said starting materials. Settling particles of the said mixed powdered material appeared to disperse in the water with the resulting formation of threads or pendant structures of such gel in otherwise unaffected portions of sea water beneath a surface gelled zone.

The resulting aqueous preparation is not stirred, a deliberate eflort being made to observe the spontaneous behavior of the said solid substance in sea water.

The resulting viscous surface layer does not appear to undergo syneresis nor to exude moisture as did the preparation in the foregoing example, but remains stably viscous over an extended period of time.

Examination of' the walls and bottom of the vessel within which the said sea water was confined, discloses the presence, as a more-or-less continuous lining of said walls and a more-or-less continuous layer across said bottom of a dense viscous preparation according to the present invention, such viscous preparation thus comprising nearly an intact cell containing relatively unaifected sea water.

The amount of such powdered solution employed in the present example is not measured precisely, but is approximately equal to one-quarter weight percent of sea water thus treated.

Example 20 Aqueous solutions of sodium polystyrene sulfonate having an average molecular weight of approximately 1,500,000 and of -methyl-3-vinyloxaZolidin-2-one having a molecular aggregation corresponding to the K-value of Fikentscher of 72.4 were prepared at a concentration of 0.5 percent by weight of total solution of each solute. Brookfield viscosities of each solution were determined, at 6 revolutions per minute. The sulfonate solution had a Brookfield viscosity of 17 centipoises while the oxazolidinone solution had a Brookfield viscosity of 4 centipoises.

Portions of separate solutions were intimately mixed and blended together with stirring to obtain a viscosityincreasing preparation of the present invention. The resulting product increased promptly and dramatically in viscosity. After approximately 1 minute of such mixing, the Brookfield viscosity of the resulting preparation was determined and was found to be 17,800 centipoises.

Portions of each of the two starting solutions were then diluted with water to obtain separate polymer solutions having a concentration of 0.05 percent of solute by weight of resulting solution. The Brookfield viscosity of the resulting sulfonate solution was measured and found to be 6.0. Repeated attempts to measure the viscosity of the resulting oxazolidinone solution ascertained that such viscosity lay within the limits of experimental error in the method of measuring viscosity employed, but the viscosity was estimated to be approximately 3.0.

Equal volumes of the said solutions were intimately mixed and blended together whereby there was obtained a mixture comprising 0.025 percent by weight of each solute in the liquid. The sum of the viscosities of such solutions was estimated to be approximately between 3.5 and 4.5.

A mixture of the said solutions was prepared employing 150 parts by volume of the sulfonated solution and 100 parts by volume .of the oxazolidinone solution. The two solutions were intimately mixed and blended together with stirring whereupon there took place a conspicuous increase in viscosity, more noticeable to a trained observer than measurable.

The Brookfield viscosity of the resulting preparation was measured at 6 revolutions per minute whereby it was ascertained that the products had a Brookfield viscosity of 13. However, the informal application to the resulting preparation of various other viscosity-increasing methods such as the bubble-rise method and the falling-ball method leads to the opinion that the Brookfield measurement of the viscosity did not altogether express the resulting increase in thickness of the preparation.

The compositions and products of the present invention are used successfully to increase the viscosity of strong mineral acids as is indicated in the following examples.

Example 21 Dry granular sodium polystyrene sulfonate was dispersed in liquid concentrated sulfuric acid. After prolonged stirring it was determined that the substance was incompletely soluble in the said acid. Therefore, with necessary precautions in view of the unusual procedure, a small amount of water was added drop-wise and with continuous stirring to the dispersion of sodium polystyrene sulfonate in sulfuric acid, employing only enough water to permit dissolving the said sulfonate compound. The precise acid concentration at which the sulfonate entirely dissolved was not ascertained but was roughly estimated to be between 60 and percent H In similar procedure a solution of 5-methyl-3-vinyl oxazolidin-Z-one in sulfuric acid was prepared. Each of the said solutions was of a viscosity determined principally by the concentration of sulfuric acid, fluid and easily poured but moderately thicker than water.

The two separate sulfuric acid solutions were then combined with mixing and stirring. The viscosity of the resulting preparations promptly increased, such increase continuing over a period of time until the resulting preparation was a soft, deformable solid which could be lifted bodily, on the employed glass stirring rod from the container in which the mixing was carried out. The product was tested and found to be active as an acid in the same degree as a corresponding aqueous sulfuric acid except that, because internal flow was obstructed, surficial portions of the acid first became exhausted and thereafter it was necessary to deform the body comprising the acid to render further portions of acid available.

Example 22 The present example was carried out in all respects as was Example 21, foregoing, except that the employed acid was phosphoric acid. The results obtained were essentially the same, the resulting preparation being of viscosity so great that it could be lifted bodily on a stirring rod.

The utilities of the novel viscosity-building substances of the present invention are in part set forth hereinbefore. Numerous other applications have been tested and the present invention found useful therein. Among these are the increasing of the viscosity with corrolary reduction of vapor pressure of aqueous ammonia solutions which are thereby rendered useful for airplane application as fertilizers of the soil for agricultural purposes. The use of aqueous ammonia in this way is well known but its airplane application has been impractical because the ammonia escapes as a gas from its aqueous solutions when such solutions are sprayed or otherwise ejected from an airplane into the air above a field to which application is desired. A thickened aqueous product which may be ejected in droplets or as solid fragments overcomes this difficulty. The preparation is deemed to be especially appropriate in the application of ammonia as fertilizer to fallow ground or to shallow water in which aquatic or seim-aquatic vegetation such as rice, is to be grown.

Also, a thickened aqueous ammonia of which the viscosity is increased to any desired level has numerous household and industrial applications as a cleansing agent. The adhering of the thickened preparation to the surface to be cleansed is greatly helped by the preparations of the present invention.

Similarly, sulfuric, phosphoric, and acetic acids which are widely used in industry as pickling or metal-surfacecleansing agents may be thickened in the manner of the present invention to viscosity of any desired degree thereby considerably enhancing their usefulness in many cleansing applications.

Prior to its hardening, a phenomenon which is generally believed to involve hydration, Portland cement is essentially an aqueous slurry having many of the properties of a liquid. When it is desired to confer upon such slurry the physical properties of a semi-solid or to increase the viscosity of such cement to inhibit its flow or deformation under the influence of gravity, the viscosityincreasing phenomenon of the present invention is use/ fully employed,

Such toilet articles as after-shave lotion, cologne water, perfumes, shampoo liquids and the like having appreciable content of lower alkanols, glycols, glycerine and the like, may be given increased viscosity with resulting increased adherence to surfaces to which they are applied in the manner of the present invention.

The aqueous slurries of natural earths employed in the well-drilling art, particularly the oil-Well drilling art, may be caused to have increased viscosity and resulting increased usefulness by the preparations of the present invention. I

In the industrial production of surfactant substances in 'bar form for domestic use, one problem has consistently been the tendency of such bars comprising synthetic detergents, When in contact with Water, to swell, disperse, and slough 06?. Another problem has been that detergent bars, while effective as sources of cleansing detergents, do not exhibit the lubricity when moist, that is to say the slipperiness, Which is commonly associated with the power to cleanse. Both these problems are simultaneously overcome by the inclusion, in a detergent bar, of a viscosity-increasing composition of the present invention. Meantime, such preparation does not interfere with the desired detergent action of such substance.

Numerous aqueous Window-cleaning preparations are on the market. These preparations uniformly suffer the disadvantage that when it is desired to apply a quantity thereof suflicient to soften and remove substantial accumulations of soil from glass or window surfaces, the aqueous preparation runs off in the manner of liquids. These preparations, thickened in the manner of the present invention do not run ofif. Moreover, the prevent viscosity building agents do not interfere with the cleansing action of such substances but rather appear to contribute to the resulting brilliance and clarity of the cleansed surface.

In another application, one of the present aqueous starting materials may be applied to one of two surfaces which are to be joined; the other may be applied to the second such surface. The surfaces are then brought to gether with gentle pressure, whereby the present viscous materials form and the surfaces are caused thereby to adhere together.

I claim:

1. A composition of Which the essential components in aqueous dispersion are a water-soluble polymer comprising recurring 3-alkenyl cyclic carbamate groups in the cyclic moiety of each of which there are from 5 to 7, inclusive, atoms and a water-soluble polyalkenyl polymer comprising recurring members of the group consisting of sulfo and carboxyl and salts thereof; the said composition being of viscosity greater than the mean of the separate viscosities of the said polymers in separate similar dispersion.

2. A composition of matter comprising, in aqueous dispersion, the product resulting from the contacting of a water-soluble polymeric 3-alkenyl cyclic carbamate in the cyclic moiety of which are from 5 to 7, inclusive, atoms with a water-soluble polyalkenyl polymer comprising recurring members of the group consisting of sulfo and carboxyl and the salts thereof, said composition being of greater viscosity than the mean of the separate viscosities of the said polymers in separate similar dispersion.

3. A composition of matter comprising, in aqueous dispersion, the product resulting from the contacting of a water-soluble polymeric 3-vinyloxazolidin-2-one and a Water soluble polyalkenyl substance upon the polymer chain of which there appear recurring moieties which are members of the group consisting of sulfo and carboxyl and the salts thereof, said composition being of greater viscosity than the mean of the viscosities of the starting materials in similar dispersion.

4. A composition of matter comprising in aqueous dispersion, the product resulting from the intimate mixing together in finely divided form in the absence of liquid medium of a water-soluble polymeric 3-vinyloxazolidin-2- 18 one compound and a water soluble polyalkenyl substance upon the polymer chain of which there are recurring moieties comprising members of the group consisting of sulfo and carboxyl and salts thereof, said dispersion being of a greater viscosity than the mean of the viscosities of the starting materials in similar dispersion.

5. A composition of matter comprising the product resulting from the intimate mixing together in aqueous dispersion of an adduct of a polymeric vinyloxazolidin-Z- one compound and a biologically active material with a polyalkenyl substance upon the polymer chain of which there are recurring moieties comprising members of the group consisting of sulfo and carboxyl and salts thereof.

6. Composition of claim 5 wherein the biologically active material is iodine.

7. Composition of claim 5 wherein the biologically active material is phenol.

8. A composition of matter comprising, dispersion, an opaque reflective agent, and resulting from the intimate mixing together soluble polymeric alkenyl substituted cyclic in the ring structure of which there are found 5 to 7, inclusive, atoms and a polyalkenyl substance upon the polymer chain of which there appear recurring structures comprising moieties selected from sulfo and carboxyl and salts thereof.

9. A composition of matter comprising, in aqueous dispersion, a surfactant and the product resulting from the intimate mixing together of a polymeric alkenyl-substituted cyclic carbamate in the ring structure of which there are from 5 to 7, inclusive, atoms and a polyalkenyl substance upon which there appear recurring structures comprising moieties selected from sulfo and carboxyl and the salts thereof.

10. A composition of matter comprising, in aqueous dispersion a herbicide and the product resulting from the contacting together of a polymeric alkenyl-substituted cyclic carbamate in the ring structure of which there are from 5 to 7, inclusive, atoms and a polyalkenyl substance upon which there appear recurring structures comprising moieties selected from sulfo and carboxyl and the salts thereof.

11. In a method of flood control, the steps of introducing into separate portions of a natural body of water a first solution comprising a water-soluble polymer comprising an N-vinyl cyclic carbamate in the ring structure of which there are from 5 to 7, inclusive, members, and a second solution comprising a polyalkenyl substance comprising recurring acidic moieties selected from sulfo and carboxyl and the salts thereof.

12. A composition of matter comprising the product resulting from the successive steps of (l) contacting of a water-soluble polymeric alkenyl cyclic carbamate in the cyclic moiety of which there are from 5 to 7, inclusive, atoms with a Water-soluble polyalkenyl polymer upon the polymer chain of which there are recurring moieties comprising members of the group consisting of sulfo and carboxyl and the salts thereof, said contacting being carried out with both said polymeric substances in aqueous solution and (2) subjecting the resulting product to evaporative removal of water.

13. Composition of claim 12, wherein the water-free product is again dispersed in Water.

14. Composition of matter comprising concentrated sulfuric acid, sodium polystyrene sulfonate, and a polymer comprising recurring N-vinyl cyclic carbamate moieties of which the ring structure contains from 5 to 7, inclusive, annular members, together with a minor content of Water, such composition being characterized by having a viscosity greater than the viscosity of any of its starting materials.

15. Composition according to claim 14 except that the employed concentrated acid is phosphoric acid.

in aqueous the product of a watercarbamate (References on following page) References Cited UNITED STATES PATENTS Shelanski 167-70 Dixon et a1. 260-41 Morgan et a1. 260-41 Roth 260-41 Drechsel 260-775 Aflieck 117-123 Gnaedinger 61-36 Walles et a1. 99-48 Walles et a1. 99-48 Walles et a1. 99-28 20 Walles et a1. 260-2393 Walles et a1. 260-307 Walles et a1. 260-775 Walles et a1. 260-775 Tousignant 167-871 Walles et a1. 260-775 Werner 260-775 LEWIS GOTTS, Primary Examiner.

1 MORRIS O. WOLK, Examiner.

S. K. ROSE, Assistant Examiner. 

10. A COMPOSITION OF MATTER COMPRISING, IN AQUEOUS DISPERSION A HERBICIDE AND THE PRODUCT RESULTING FROM THE CONTACTING TOGETHER OF A POLYMERIC ALKENYL-SUBSTITUTED CYCLIC CARBAMATE IN THE RING STRUCTURE OF WHICH THERE ARE FROM 5 TO 7, INCLUSIVE, ATOMS AND A POLYALKENYL SUBSTANCE UPON WHICH THERE APPEAR RECURRING STRUCTURES COMPRISING MOIETIES SELECTED FROM SULFO AND CARBOXYL AND THE SALTS THEREOF. 